/*- * Copyright (c) 2001-2003 * Fraunhofer Institute for Open Communication Systems (FhG Fokus). * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * Author: Hartmut Brandt * * ForeHE driver. * * This file contains the module and driver infrastructure stuff as well * as a couple of utility functions and the entire initialisation. */ #include __FBSDID("$FreeBSD$"); #include "opt_inet.h" #include "opt_natm.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef ENABLE_BPF #include #endif #include #include #include #include #include #include #include #include #include #include #include #include static const struct { uint16_t vid; uint16_t did; const char *name; } hatm_devs[] = { { 0x1127, 0x400, "FORE HE" }, { 0, 0, NULL } }; SYSCTL_DECL(_hw_atm); MODULE_DEPEND(hatm, utopia, 1, 1, 1); MODULE_DEPEND(hatm, pci, 1, 1, 1); MODULE_DEPEND(hatm, atm, 1, 1, 1); #define EEPROM_DELAY 400 /* microseconds */ /* Read from EEPROM 0000 0011b */ static const uint32_t readtab[] = { HE_REGM_HOST_PROM_SEL | HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, /* 0 */ HE_REGM_HOST_PROM_CLOCK, 0, /* 0 */ HE_REGM_HOST_PROM_CLOCK, 0, /* 0 */ HE_REGM_HOST_PROM_CLOCK, 0, /* 0 */ HE_REGM_HOST_PROM_CLOCK, 0, /* 0 */ HE_REGM_HOST_PROM_CLOCK, HE_REGM_HOST_PROM_DATA_IN, /* 0 */ HE_REGM_HOST_PROM_CLOCK | HE_REGM_HOST_PROM_DATA_IN, HE_REGM_HOST_PROM_DATA_IN, /* 1 */ HE_REGM_HOST_PROM_CLOCK | HE_REGM_HOST_PROM_DATA_IN, HE_REGM_HOST_PROM_DATA_IN, /* 1 */ }; static const uint32_t clocktab[] = { 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0, HE_REGM_HOST_PROM_CLOCK, 0 }; /* * Convert cell rate to ATM Forum format */ u_int hatm_cps2atmf(uint32_t pcr) { u_int e; if (pcr == 0) return (0); pcr <<= 9; e = 0; while (pcr > (1024 - 1)) { e++; pcr >>= 1; } return ((1 << 14) | (e << 9) | (pcr & 0x1ff)); } u_int hatm_atmf2cps(uint32_t fcr) { fcr &= 0x7fff; return ((1 << ((fcr >> 9) & 0x1f)) * (512 + (fcr & 0x1ff)) / 512 * (fcr >> 14)); } /************************************************************ * * Initialisation */ /* * Probe for a HE controller */ static int hatm_probe(device_t dev) { int i; for (i = 0; hatm_devs[i].name; i++) if (pci_get_vendor(dev) == hatm_devs[i].vid && pci_get_device(dev) == hatm_devs[i].did) { device_set_desc(dev, hatm_devs[i].name); return (BUS_PROBE_DEFAULT); } return (ENXIO); } /* * Allocate and map DMA-able memory. We support only contiguous mappings. */ static void dmaload_helper(void *arg, bus_dma_segment_t *segs, int nsegs, int error) { if (error) return; KASSERT(nsegs == 1, ("too many segments for DMA: %d", nsegs)); KASSERT(segs[0].ds_addr <= 0xffffffffUL, ("phys addr too large %lx", (u_long)segs[0].ds_addr)); *(bus_addr_t *)arg = segs[0].ds_addr; } static int hatm_alloc_dmamem(struct hatm_softc *sc, const char *what, struct dmamem *mem) { int error; mem->base = NULL; /* * Alignement does not work in the bus_dmamem_alloc function below * on FreeBSD. malloc seems to align objects at least to the object * size so increase the size to the alignment if the size is lesser * than the alignemnt. * XXX on sparc64 this is (probably) not needed. */ if (mem->size < mem->align) mem->size = mem->align; error = bus_dma_tag_create(sc->parent_tag, mem->align, 0, BUS_SPACE_MAXADDR_32BIT, BUS_SPACE_MAXADDR, NULL, NULL, mem->size, 1, BUS_SPACE_MAXSIZE_32BIT, BUS_DMA_ALLOCNOW, NULL, NULL, &mem->tag); if (error) { if_printf(sc->ifp, "DMA tag create (%s)\n", what); return (error); } error = bus_dmamem_alloc(mem->tag, &mem->base, 0, &mem->map); if (error) { if_printf(sc->ifp, "DMA mem alloc (%s): %d\n", what, error); bus_dma_tag_destroy(mem->tag); mem->base = NULL; return (error); } error = bus_dmamap_load(mem->tag, mem->map, mem->base, mem->size, dmaload_helper, &mem->paddr, BUS_DMA_NOWAIT); if (error) { if_printf(sc->ifp, "DMA map load (%s): %d\n", what, error); bus_dmamem_free(mem->tag, mem->base, mem->map); bus_dma_tag_destroy(mem->tag); mem->base = NULL; return (error); } DBG(sc, DMA, ("%s S/A/V/P 0x%x 0x%x %p 0x%lx", what, mem->size, mem->align, mem->base, (u_long)mem->paddr)); return (0); } /* * Destroy all the resources of an DMA-able memory region. */ static void hatm_destroy_dmamem(struct dmamem *mem) { if (mem->base != NULL) { bus_dmamap_unload(mem->tag, mem->map); bus_dmamem_free(mem->tag, mem->base, mem->map); (void)bus_dma_tag_destroy(mem->tag); mem->base = NULL; } } /* * Initialize/destroy DMA maps for the large pool 0 */ static void hatm_destroy_rmaps(struct hatm_softc *sc) { u_int b; DBG(sc, ATTACH, ("destroying rmaps and lbuf pointers...")); if (sc->rmaps != NULL) { for (b = 0; b < sc->lbufs_size; b++) bus_dmamap_destroy(sc->mbuf_tag, sc->rmaps[b]); free(sc->rmaps, M_DEVBUF); } if (sc->lbufs != NULL) free(sc->lbufs, M_DEVBUF); } static void hatm_init_rmaps(struct hatm_softc *sc) { u_int b; int err; DBG(sc, ATTACH, ("allocating rmaps and lbuf pointers...")); sc->lbufs = malloc(sizeof(sc->lbufs[0]) * sc->lbufs_size, M_DEVBUF, M_ZERO | M_WAITOK); /* allocate and create the DMA maps for the large pool */ sc->rmaps = malloc(sizeof(sc->rmaps[0]) * sc->lbufs_size, M_DEVBUF, M_WAITOK); for (b = 0; b < sc->lbufs_size; b++) { err = bus_dmamap_create(sc->mbuf_tag, 0, &sc->rmaps[b]); if (err != 0) panic("bus_dmamap_create: %d\n", err); } } /* * Initialize and destroy small mbuf page pointers and pages */ static void hatm_destroy_smbufs(struct hatm_softc *sc) { u_int i, b; struct mbuf_page *pg; struct mbuf_chunk_hdr *h; if (sc->mbuf_pages != NULL) { for (i = 0; i < sc->mbuf_npages; i++) { pg = sc->mbuf_pages[i]; for (b = 0; b < pg->hdr.nchunks; b++) { h = (struct mbuf_chunk_hdr *) ((char *)pg + b * pg->hdr.chunksize + pg->hdr.hdroff); if (h->flags & MBUF_CARD) if_printf(sc->ifp, "%s -- mbuf page=%u card buf %u\n", __func__, i, b); if (h->flags & MBUF_USED) if_printf(sc->ifp, "%s -- mbuf page=%u used buf %u\n", __func__, i, b); } bus_dmamap_unload(sc->mbuf_tag, pg->hdr.map); bus_dmamap_destroy(sc->mbuf_tag, pg->hdr.map); free(pg, M_DEVBUF); } free(sc->mbuf_pages, M_DEVBUF); } } static void hatm_init_smbufs(struct hatm_softc *sc) { sc->mbuf_pages = malloc(sizeof(sc->mbuf_pages[0]) * sc->mbuf_max_pages, M_DEVBUF, M_WAITOK); sc->mbuf_npages = 0; } /* * Initialize/destroy TPDs. This is called from attach/detach. */ static void hatm_destroy_tpds(struct hatm_softc *sc) { struct tpd *t; if (sc->tpds.base == NULL) return; DBG(sc, ATTACH, ("releasing TPDs ...")); if (sc->tpd_nfree != sc->tpd_total) if_printf(sc->ifp, "%u tpds still in use from %u\n", sc->tpd_total - sc->tpd_nfree, sc->tpd_total); while ((t = SLIST_FIRST(&sc->tpd_free)) != NULL) { SLIST_REMOVE_HEAD(&sc->tpd_free, link); bus_dmamap_destroy(sc->tx_tag, t->map); } hatm_destroy_dmamem(&sc->tpds); free(sc->tpd_used, M_DEVBUF); DBG(sc, ATTACH, ("... done")); } static int hatm_init_tpds(struct hatm_softc *sc) { int error; u_int i; struct tpd *t; DBG(sc, ATTACH, ("allocating %u TPDs and maps ...", sc->tpd_total)); error = hatm_alloc_dmamem(sc, "TPD memory", &sc->tpds); if (error != 0) { DBG(sc, ATTACH, ("... dmamem error=%d", error)); return (error); } /* put all the TPDs on the free list and allocate DMA maps */ for (i = 0; i < sc->tpd_total; i++) { t = TPD_ADDR(sc, i); t->no = i; t->mbuf = NULL; error = bus_dmamap_create(sc->tx_tag, 0, &t->map); if (error != 0) { DBG(sc, ATTACH, ("... dmamap error=%d", error)); while ((t = SLIST_FIRST(&sc->tpd_free)) != NULL) { SLIST_REMOVE_HEAD(&sc->tpd_free, link); bus_dmamap_destroy(sc->tx_tag, t->map); } hatm_destroy_dmamem(&sc->tpds); return (error); } SLIST_INSERT_HEAD(&sc->tpd_free, t, link); } /* allocate and zero bitmap */ sc->tpd_used = malloc(sizeof(uint8_t) * (sc->tpd_total + 7) / 8, M_DEVBUF, M_ZERO | M_WAITOK); sc->tpd_nfree = sc->tpd_total; DBG(sc, ATTACH, ("... done")); return (0); } /* * Free all the TPDs that where given to the card. * An mbuf chain may be attached to a TPD - free it also and * unload its associated DMA map. */ static void hatm_stop_tpds(struct hatm_softc *sc) { u_int i; struct tpd *t; DBG(sc, ATTACH, ("free TPDs ...")); for (i = 0; i < sc->tpd_total; i++) { if (TPD_TST_USED(sc, i)) { t = TPD_ADDR(sc, i); if (t->mbuf) { m_freem(t->mbuf); t->mbuf = NULL; bus_dmamap_unload(sc->tx_tag, t->map); } TPD_CLR_USED(sc, i); SLIST_INSERT_HEAD(&sc->tpd_free, t, link); sc->tpd_nfree++; } } } /* * This frees ALL resources of this interface and leaves the structure * in an indeterminate state. This is called just before detaching or * on a failed attach. No lock should be held. */ static void hatm_destroy(struct hatm_softc *sc) { u_int cid; bus_teardown_intr(sc->dev, sc->irqres, sc->ih); hatm_destroy_rmaps(sc); hatm_destroy_smbufs(sc); hatm_destroy_tpds(sc); if (sc->vcc_zone != NULL) { for (cid = 0; cid < HE_MAX_VCCS; cid++) if (sc->vccs[cid] != NULL) uma_zfree(sc->vcc_zone, sc->vccs[cid]); uma_zdestroy(sc->vcc_zone); } /* * Release all memory allocated to the various queues and * Status pages. These have there own flag which shows whether * they are really allocated. */ hatm_destroy_dmamem(&sc->irq_0.mem); hatm_destroy_dmamem(&sc->rbp_s0.mem); hatm_destroy_dmamem(&sc->rbp_l0.mem); hatm_destroy_dmamem(&sc->rbp_s1.mem); hatm_destroy_dmamem(&sc->rbrq_0.mem); hatm_destroy_dmamem(&sc->rbrq_1.mem); hatm_destroy_dmamem(&sc->tbrq.mem); hatm_destroy_dmamem(&sc->tpdrq.mem); hatm_destroy_dmamem(&sc->hsp_mem); if (sc->irqres != NULL) bus_release_resource(sc->dev, SYS_RES_IRQ, sc->irqid, sc->irqres); if (sc->tx_tag != NULL) if (bus_dma_tag_destroy(sc->tx_tag)) if_printf(sc->ifp, "mbuf DMA tag busy\n"); if (sc->mbuf_tag != NULL) if (bus_dma_tag_destroy(sc->mbuf_tag)) if_printf(sc->ifp, "mbuf DMA tag busy\n"); if (sc->parent_tag != NULL) if (bus_dma_tag_destroy(sc->parent_tag)) if_printf(sc->ifp, "parent DMA tag busy\n"); if (sc->memres != NULL) bus_release_resource(sc->dev, SYS_RES_MEMORY, sc->memid, sc->memres); sysctl_ctx_free(&sc->sysctl_ctx); cv_destroy(&sc->cv_rcclose); cv_destroy(&sc->vcc_cv); mtx_destroy(&sc->mtx); if (sc->ifp != NULL) if_free(sc->ifp); } /* * 4.4 Card reset */ static int hatm_reset(struct hatm_softc *sc) { u_int v, count; WRITE4(sc, HE_REGO_RESET_CNTL, 0x00); BARRIER_W(sc); WRITE4(sc, HE_REGO_RESET_CNTL, 0xff); BARRIER_RW(sc); count = 0; while (((v = READ4(sc, HE_REGO_RESET_CNTL)) & HE_REGM_RESET_STATE) == 0) { BARRIER_R(sc); if (++count == 100) { if_printf(sc->ifp, "reset failed\n"); return (ENXIO); } DELAY(1000); } return (0); } /* * 4.5 Set Bus Width */ static void hatm_init_bus_width(struct hatm_softc *sc) { uint32_t v, v1; v = READ4(sc, HE_REGO_HOST_CNTL); BARRIER_R(sc); if (v & HE_REGM_HOST_BUS64) { sc->pci64 = 1; v1 = pci_read_config(sc->dev, HE_PCIR_GEN_CNTL_0, 4); v1 |= HE_PCIM_CTL0_64BIT; pci_write_config(sc->dev, HE_PCIR_GEN_CNTL_0, v1, 4); v |= HE_REGM_HOST_DESC_RD64 | HE_REGM_HOST_DATA_RD64 | HE_REGM_HOST_DATA_WR64; WRITE4(sc, HE_REGO_HOST_CNTL, v); BARRIER_W(sc); } else { sc->pci64 = 0; v = pci_read_config(sc->dev, HE_PCIR_GEN_CNTL_0, 4); v &= ~HE_PCIM_CTL0_64BIT; pci_write_config(sc->dev, HE_PCIR_GEN_CNTL_0, v, 4); } } /* * 4.6 Set Host Endianess */ static void hatm_init_endianess(struct hatm_softc *sc) { uint32_t v; v = READ4(sc, HE_REGO_LB_SWAP); BARRIER_R(sc); #if BYTE_ORDER == BIG_ENDIAN v |= HE_REGM_LBSWAP_INTR_SWAP | HE_REGM_LBSWAP_DESC_WR_SWAP | HE_REGM_LBSWAP_BIG_ENDIAN; v &= ~(HE_REGM_LBSWAP_DATA_WR_SWAP | HE_REGM_LBSWAP_DESC_RD_SWAP | HE_REGM_LBSWAP_DATA_RD_SWAP); #else v &= ~(HE_REGM_LBSWAP_DATA_WR_SWAP | HE_REGM_LBSWAP_DESC_RD_SWAP | HE_REGM_LBSWAP_DATA_RD_SWAP | HE_REGM_LBSWAP_INTR_SWAP | HE_REGM_LBSWAP_DESC_WR_SWAP | HE_REGM_LBSWAP_BIG_ENDIAN); #endif if (sc->he622) v |= HE_REGM_LBSWAP_XFER_SIZE; WRITE4(sc, HE_REGO_LB_SWAP, v); BARRIER_W(sc); } /* * 4.7 Read EEPROM */ static uint8_t hatm_read_prom_byte(struct hatm_softc *sc, u_int addr) { uint32_t val, tmp_read, byte_read; u_int i, j; int n; val = READ4(sc, HE_REGO_HOST_CNTL); val &= HE_REGM_HOST_PROM_BITS; BARRIER_R(sc); val |= HE_REGM_HOST_PROM_WREN; WRITE4(sc, HE_REGO_HOST_CNTL, val); BARRIER_W(sc); /* send READ */ for (i = 0; i < sizeof(readtab) / sizeof(readtab[0]); i++) { WRITE4(sc, HE_REGO_HOST_CNTL, val | readtab[i]); BARRIER_W(sc); DELAY(EEPROM_DELAY); } /* send ADDRESS */ for (n = 7, j = 0; n >= 0; n--) { WRITE4(sc, HE_REGO_HOST_CNTL, val | clocktab[j++] | (((addr >> n) & 1 ) << HE_REGS_HOST_PROM_DATA_IN)); BARRIER_W(sc); DELAY(EEPROM_DELAY); WRITE4(sc, HE_REGO_HOST_CNTL, val | clocktab[j++] | (((addr >> n) & 1 ) << HE_REGS_HOST_PROM_DATA_IN)); BARRIER_W(sc); DELAY(EEPROM_DELAY); } val &= ~HE_REGM_HOST_PROM_WREN; WRITE4(sc, HE_REGO_HOST_CNTL, val); BARRIER_W(sc); /* read DATA */ byte_read = 0; for (n = 7, j = 0; n >= 0; n--) { WRITE4(sc, HE_REGO_HOST_CNTL, val | clocktab[j++]); BARRIER_W(sc); DELAY(EEPROM_DELAY); tmp_read = READ4(sc, HE_REGO_HOST_CNTL); byte_read |= (uint8_t)(((tmp_read & HE_REGM_HOST_PROM_DATA_OUT) >> HE_REGS_HOST_PROM_DATA_OUT) << n); WRITE4(sc, HE_REGO_HOST_CNTL, val | clocktab[j++]); BARRIER_W(sc); DELAY(EEPROM_DELAY); } WRITE4(sc, HE_REGO_HOST_CNTL, val | clocktab[j++]); BARRIER_W(sc); DELAY(EEPROM_DELAY); return (byte_read); } static void hatm_init_read_eeprom(struct hatm_softc *sc) { u_int n, count; u_char byte; uint32_t v; for (n = count = 0; count < HE_EEPROM_PROD_ID_LEN; count++) { byte = hatm_read_prom_byte(sc, HE_EEPROM_PROD_ID + count); if (n > 0 || byte != ' ') sc->prod_id[n++] = byte; } while (n > 0 && sc->prod_id[n-1] == ' ') n--; sc->prod_id[n] = '\0'; for (n = count = 0; count < HE_EEPROM_REV_LEN; count++) { byte = hatm_read_prom_byte(sc, HE_EEPROM_REV + count); if (n > 0 || byte != ' ') sc->rev[n++] = byte; } while (n > 0 && sc->rev[n-1] == ' ') n--; sc->rev[n] = '\0'; IFP2IFATM(sc->ifp)->mib.hw_version = sc->rev[0]; IFP2IFATM(sc->ifp)->mib.serial = hatm_read_prom_byte(sc, HE_EEPROM_M_SN + 0) << 0; IFP2IFATM(sc->ifp)->mib.serial |= hatm_read_prom_byte(sc, HE_EEPROM_M_SN + 1) << 8; IFP2IFATM(sc->ifp)->mib.serial |= hatm_read_prom_byte(sc, HE_EEPROM_M_SN + 2) << 16; IFP2IFATM(sc->ifp)->mib.serial |= hatm_read_prom_byte(sc, HE_EEPROM_M_SN + 3) << 24; v = hatm_read_prom_byte(sc, HE_EEPROM_MEDIA + 0) << 0; v |= hatm_read_prom_byte(sc, HE_EEPROM_MEDIA + 1) << 8; v |= hatm_read_prom_byte(sc, HE_EEPROM_MEDIA + 2) << 16; v |= hatm_read_prom_byte(sc, HE_EEPROM_MEDIA + 3) << 24; switch (v) { case HE_MEDIA_UTP155: IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_UTP_155; IFP2IFATM(sc->ifp)->mib.pcr = ATM_RATE_155M; break; case HE_MEDIA_MMF155: IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_MM_155; IFP2IFATM(sc->ifp)->mib.pcr = ATM_RATE_155M; break; case HE_MEDIA_MMF622: IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_MM_622; IFP2IFATM(sc->ifp)->mib.device = ATM_DEVICE_HE622; IFP2IFATM(sc->ifp)->mib.pcr = ATM_RATE_622M; sc->he622 = 1; break; case HE_MEDIA_SMF155: IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_SM_155; IFP2IFATM(sc->ifp)->mib.pcr = ATM_RATE_155M; break; case HE_MEDIA_SMF622: IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_SM_622; IFP2IFATM(sc->ifp)->mib.device = ATM_DEVICE_HE622; IFP2IFATM(sc->ifp)->mib.pcr = ATM_RATE_622M; sc->he622 = 1; break; } IFP2IFATM(sc->ifp)->mib.esi[0] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 0); IFP2IFATM(sc->ifp)->mib.esi[1] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 1); IFP2IFATM(sc->ifp)->mib.esi[2] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 2); IFP2IFATM(sc->ifp)->mib.esi[3] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 3); IFP2IFATM(sc->ifp)->mib.esi[4] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 4); IFP2IFATM(sc->ifp)->mib.esi[5] = hatm_read_prom_byte(sc, HE_EEPROM_MAC + 5); } /* * Clear unused interrupt queue */ static void hatm_clear_irq(struct hatm_softc *sc, u_int group) { WRITE4(sc, HE_REGO_IRQ_BASE(group), 0); WRITE4(sc, HE_REGO_IRQ_HEAD(group), 0); WRITE4(sc, HE_REGO_IRQ_CNTL(group), 0); WRITE4(sc, HE_REGO_IRQ_DATA(group), 0); } /* * 4.10 Initialize interrupt queues */ static void hatm_init_irq(struct hatm_softc *sc, struct heirq *q, u_int group) { u_int i; if (q->size == 0) { hatm_clear_irq(sc, group); return; } q->group = group; q->sc = sc; q->irq = q->mem.base; q->head = 0; q->tailp = q->irq + (q->size - 1); *q->tailp = 0; for (i = 0; i < q->size; i++) q->irq[i] = HE_REGM_ITYPE_INVALID; WRITE4(sc, HE_REGO_IRQ_BASE(group), q->mem.paddr); WRITE4(sc, HE_REGO_IRQ_HEAD(group), ((q->size - 1) << HE_REGS_IRQ_HEAD_SIZE) | (q->thresh << HE_REGS_IRQ_HEAD_THRESH)); WRITE4(sc, HE_REGO_IRQ_CNTL(group), q->line); WRITE4(sc, HE_REGO_IRQ_DATA(group), 0); } /* * 5.1.3 Initialize connection memory */ static void hatm_init_cm(struct hatm_softc *sc) { u_int rsra, mlbm, rabr, numbuffs; u_int tsra, tabr, mtpd; u_int n; for (n = 0; n < HE_CONFIG_TXMEM; n++) WRITE_TCM4(sc, n, 0); for (n = 0; n < HE_CONFIG_RXMEM; n++) WRITE_RCM4(sc, n, 0); numbuffs = sc->r0_numbuffs + sc->r1_numbuffs + sc->tx_numbuffs; rsra = 0; mlbm = ((rsra + IFP2IFATM(sc->ifp)->mib.max_vccs * 8) + 0x7ff) & ~0x7ff; rabr = ((mlbm + numbuffs * 2) + 0x7ff) & ~0x7ff; sc->rsrb = ((rabr + 2048) + (2 * IFP2IFATM(sc->ifp)->mib.max_vccs - 1)) & ~(2 * IFP2IFATM(sc->ifp)->mib.max_vccs - 1); tsra = 0; sc->tsrb = tsra + IFP2IFATM(sc->ifp)->mib.max_vccs * 8; sc->tsrc = sc->tsrb + IFP2IFATM(sc->ifp)->mib.max_vccs * 4; sc->tsrd = sc->tsrc + IFP2IFATM(sc->ifp)->mib.max_vccs * 2; tabr = sc->tsrd + IFP2IFATM(sc->ifp)->mib.max_vccs * 1; mtpd = ((tabr + 1024) + (16 * IFP2IFATM(sc->ifp)->mib.max_vccs - 1)) & ~(16 * IFP2IFATM(sc->ifp)->mib.max_vccs - 1); DBG(sc, ATTACH, ("rsra=%x mlbm=%x rabr=%x rsrb=%x", rsra, mlbm, rabr, sc->rsrb)); DBG(sc, ATTACH, ("tsra=%x tsrb=%x tsrc=%x tsrd=%x tabr=%x mtpd=%x", tsra, sc->tsrb, sc->tsrc, sc->tsrd, tabr, mtpd)); WRITE4(sc, HE_REGO_TSRB_BA, sc->tsrb); WRITE4(sc, HE_REGO_TSRC_BA, sc->tsrc); WRITE4(sc, HE_REGO_TSRD_BA, sc->tsrd); WRITE4(sc, HE_REGO_TMABR_BA, tabr); WRITE4(sc, HE_REGO_TPD_BA, mtpd); WRITE4(sc, HE_REGO_RCMRSRB_BA, sc->rsrb); WRITE4(sc, HE_REGO_RCMLBM_BA, mlbm); WRITE4(sc, HE_REGO_RCMABR_BA, rabr); BARRIER_W(sc); } /* * 5.1.4 Initialize Local buffer Pools */ static void hatm_init_rx_buffer_pool(struct hatm_softc *sc, u_int num, /* bank */ u_int start, /* start row */ u_int numbuffs /* number of entries */ ) { u_int row_size; /* bytes per row */ uint32_t row_addr; /* start address of this row */ u_int lbuf_size; /* bytes per lbuf */ u_int lbufs_per_row; /* number of lbufs per memory row */ uint32_t lbufd_index; /* index of lbuf descriptor */ uint32_t lbufd_addr; /* address of lbuf descriptor */ u_int lbuf_row_cnt; /* current lbuf in current row */ uint32_t lbuf_addr; /* address of current buffer */ u_int i; row_size = sc->bytes_per_row; row_addr = start * row_size; lbuf_size = sc->cells_per_lbuf * 48; lbufs_per_row = sc->cells_per_row / sc->cells_per_lbuf; /* descriptor index */ lbufd_index = num; /* 2 words per entry */ lbufd_addr = READ4(sc, HE_REGO_RCMLBM_BA) + lbufd_index * 2; /* write head of queue */ WRITE4(sc, HE_REGO_RLBF_H(num), lbufd_index); lbuf_row_cnt = 0; for (i = 0; i < numbuffs; i++) { lbuf_addr = (row_addr + lbuf_row_cnt * lbuf_size) / 32; WRITE_RCM4(sc, lbufd_addr, lbuf_addr); lbufd_index += 2; WRITE_RCM4(sc, lbufd_addr + 1, lbufd_index); if (++lbuf_row_cnt == lbufs_per_row) { lbuf_row_cnt = 0; row_addr += row_size; } lbufd_addr += 2 * 2; } WRITE4(sc, HE_REGO_RLBF_T(num), lbufd_index - 2); WRITE4(sc, HE_REGO_RLBF_C(num), numbuffs); BARRIER_W(sc); } static void hatm_init_tx_buffer_pool(struct hatm_softc *sc, u_int start, /* start row */ u_int numbuffs /* number of entries */ ) { u_int row_size; /* bytes per row */ uint32_t row_addr; /* start address of this row */ u_int lbuf_size; /* bytes per lbuf */ u_int lbufs_per_row; /* number of lbufs per memory row */ uint32_t lbufd_index; /* index of lbuf descriptor */ uint32_t lbufd_addr; /* address of lbuf descriptor */ u_int lbuf_row_cnt; /* current lbuf in current row */ uint32_t lbuf_addr; /* address of current buffer */ u_int i; row_size = sc->bytes_per_row; row_addr = start * row_size; lbuf_size = sc->cells_per_lbuf * 48; lbufs_per_row = sc->cells_per_row / sc->cells_per_lbuf; /* descriptor index */ lbufd_index = sc->r0_numbuffs + sc->r1_numbuffs; /* 2 words per entry */ lbufd_addr = READ4(sc, HE_REGO_RCMLBM_BA) + lbufd_index * 2; /* write head of queue */ WRITE4(sc, HE_REGO_TLBF_H, lbufd_index); lbuf_row_cnt = 0; for (i = 0; i < numbuffs; i++) { lbuf_addr = (row_addr + lbuf_row_cnt * lbuf_size) / 32; WRITE_RCM4(sc, lbufd_addr, lbuf_addr); lbufd_index++; WRITE_RCM4(sc, lbufd_addr + 1, lbufd_index); if (++lbuf_row_cnt == lbufs_per_row) { lbuf_row_cnt = 0; row_addr += row_size; } lbufd_addr += 2; } WRITE4(sc, HE_REGO_TLBF_T, lbufd_index - 1); BARRIER_W(sc); } /* * 5.1.5 Initialize Intermediate Receive Queues */ static void hatm_init_imed_queues(struct hatm_softc *sc) { u_int n; if (sc->he622) { for (n = 0; n < 8; n++) { WRITE4(sc, HE_REGO_INMQ_S(n), 0x10*n+0x000f); WRITE4(sc, HE_REGO_INMQ_L(n), 0x10*n+0x200f); } } else { for (n = 0; n < 8; n++) { WRITE4(sc, HE_REGO_INMQ_S(n), n); WRITE4(sc, HE_REGO_INMQ_L(n), n+0x8); } } } /* * 5.1.7 Init CS block */ static void hatm_init_cs_block(struct hatm_softc *sc) { u_int n, i; u_int clkfreg, cellrate, decr, tmp; static const uint32_t erthr[2][5][3] = HE_REGT_CS_ERTHR; static const uint32_t erctl[2][3] = HE_REGT_CS_ERCTL; static const uint32_t erstat[2][2] = HE_REGT_CS_ERSTAT; static const uint32_t rtfwr[2] = HE_REGT_CS_RTFWR; static const uint32_t rtatr[2] = HE_REGT_CS_RTATR; static const uint32_t bwalloc[2][6] = HE_REGT_CS_BWALLOC; static const uint32_t orcf[2][2] = HE_REGT_CS_ORCF; /* Clear Rate Controller Start Times and Occupied Flags */ for (n = 0; n < 32; n++) WRITE_MBOX4(sc, HE_REGO_CS_STTIM(n), 0); clkfreg = sc->he622 ? HE_622_CLOCK : HE_155_CLOCK; cellrate = sc->he622 ? ATM_RATE_622M : ATM_RATE_155M; decr = cellrate / 32; for (n = 0; n < 16; n++) { tmp = clkfreg / cellrate; WRITE_MBOX4(sc, HE_REGO_CS_TGRLD(n), tmp - 1); cellrate -= decr; } i = (sc->cells_per_lbuf == 2) ? 0 :(sc->cells_per_lbuf == 4) ? 1 : 2; /* table 5.2 */ WRITE_MBOX4(sc, HE_REGO_CS_ERTHR0, erthr[sc->he622][0][i]); WRITE_MBOX4(sc, HE_REGO_CS_ERTHR1, erthr[sc->he622][1][i]); WRITE_MBOX4(sc, HE_REGO_CS_ERTHR2, erthr[sc->he622][2][i]); WRITE_MBOX4(sc, HE_REGO_CS_ERTHR3, erthr[sc->he622][3][i]); WRITE_MBOX4(sc, HE_REGO_CS_ERTHR4, erthr[sc->he622][4][i]); WRITE_MBOX4(sc, HE_REGO_CS_ERCTL0, erctl[sc->he622][0]); WRITE_MBOX4(sc, HE_REGO_CS_ERCTL1, erctl[sc->he622][1]); WRITE_MBOX4(sc, HE_REGO_CS_ERCTL2, erctl[sc->he622][2]); WRITE_MBOX4(sc, HE_REGO_CS_ERSTAT0, erstat[sc->he622][0]); WRITE_MBOX4(sc, HE_REGO_CS_ERSTAT1, erstat[sc->he622][1]); WRITE_MBOX4(sc, HE_REGO_CS_RTFWR, rtfwr[sc->he622]); WRITE_MBOX4(sc, HE_REGO_CS_RTATR, rtatr[sc->he622]); WRITE_MBOX4(sc, HE_REGO_CS_TFBSET, bwalloc[sc->he622][0]); WRITE_MBOX4(sc, HE_REGO_CS_WCRMAX, bwalloc[sc->he622][1]); WRITE_MBOX4(sc, HE_REGO_CS_WCRMIN, bwalloc[sc->he622][2]); WRITE_MBOX4(sc, HE_REGO_CS_WCRINC, bwalloc[sc->he622][3]); WRITE_MBOX4(sc, HE_REGO_CS_WCRDEC, bwalloc[sc->he622][4]); WRITE_MBOX4(sc, HE_REGO_CS_WCRCEIL, bwalloc[sc->he622][5]); WRITE_MBOX4(sc, HE_REGO_CS_OTPPER, orcf[sc->he622][0]); WRITE_MBOX4(sc, HE_REGO_CS_OTWPER, orcf[sc->he622][1]); WRITE_MBOX4(sc, HE_REGO_CS_OTTLIM, 8); for (n = 0; n < 8; n++) WRITE_MBOX4(sc, HE_REGO_CS_HGRRT(n), 0); } /* * 5.1.8 CS Block Connection Memory Initialisation */ static void hatm_init_cs_block_cm(struct hatm_softc *sc) { u_int n, i; u_int expt, mant, etrm, wcr, ttnrm, tnrm; uint32_t rate; uint32_t clkfreq, cellrate, decr; uint32_t *rg, rtg, val = 0; uint64_t drate; u_int buf, buf_limit; uint32_t base = READ4(sc, HE_REGO_RCMABR_BA); for (n = 0; n < HE_REGL_CM_GQTBL; n++) WRITE_RCM4(sc, base + HE_REGO_CM_GQTBL + n, 0); for (n = 0; n < HE_REGL_CM_RGTBL; n++) WRITE_RCM4(sc, base + HE_REGO_CM_RGTBL + n, 0); tnrm = 0; for (n = 0; n < HE_REGL_CM_TNRMTBL * 4; n++) { expt = (n >> 5) & 0x1f; mant = ((n & 0x18) << 4) | 0x7f; wcr = (1 << expt) * (mant + 512) / 512; etrm = n & 0x7; ttnrm = wcr / 10 / (1 << etrm); if (ttnrm > 255) ttnrm = 255; else if(ttnrm < 2) ttnrm = 2; tnrm = (tnrm << 8) | (ttnrm & 0xff); if (n % 4 == 0) WRITE_RCM4(sc, base + HE_REGO_CM_TNRMTBL + (n/4), tnrm); } clkfreq = sc->he622 ? HE_622_CLOCK : HE_155_CLOCK; buf_limit = 4; cellrate = sc->he622 ? ATM_RATE_622M : ATM_RATE_155M; decr = cellrate / 32; /* compute GRID top row in 1000 * cps */ for (n = 0; n < 16; n++) { u_int interval = clkfreq / cellrate; sc->rate_grid[0][n] = (u_int64_t)clkfreq * 1000 / interval; cellrate -= decr; } /* compute the other rows according to 2.4 */ for (i = 1; i < 16; i++) for (n = 0; n < 16; n++) sc->rate_grid[i][n] = sc->rate_grid[i-1][n] / ((i < 14) ? 2 : 4); /* first entry is line rate */ n = hatm_cps2atmf(sc->he622 ? ATM_RATE_622M : ATM_RATE_155M); expt = (n >> 9) & 0x1f; mant = n & 0x1f0; sc->rate_grid[0][0] = (u_int64_t)(1<he622 ? ATM_RATE_622M : ATM_RATE_155M; rg = &sc->rate_grid[15][15]; for (rate = 0; rate < 2 * HE_REGL_CM_RTGTBL; rate++) { /* unpack the ATMF rate */ expt = rate >> 5; mant = (rate & 0x1f) << 4; /* get the cell rate - minimum is 10 per second */ drate = (uint64_t)(1 << expt) * 1000 * (mant + 512) / 512; if (drate < 10 * 1000) drate = 10 * 1000; /* now look up the grid index */ while (drate >= *rg && rg-- > &sc->rate_grid[0][0]) ; rg++; rtg = rg - &sc->rate_grid[0][0]; /* now compute the buffer limit */ buf = drate * sc->tx_numbuffs / (cellrate * 2) / 1000; if (buf == 0) buf = 1; else if (buf > buf_limit) buf = buf_limit; /* make value */ val = (val << 16) | (rtg << 8) | buf; /* write */ if (rate % 2 == 1) WRITE_RCM4(sc, base + HE_REGO_CM_RTGTBL + rate/2, val); } } /* * Clear an unused receive group buffer pool */ static void hatm_clear_rpool(struct hatm_softc *sc, u_int group, u_int large) { WRITE4(sc, HE_REGO_RBP_S(large, group), 0); WRITE4(sc, HE_REGO_RBP_T(large, group), 0); WRITE4(sc, HE_REGO_RBP_QI(large, group), 1); WRITE4(sc, HE_REGO_RBP_BL(large, group), 0); } /* * Initialize a receive group buffer pool */ static void hatm_init_rpool(struct hatm_softc *sc, struct herbp *q, u_int group, u_int large) { if (q->size == 0) { hatm_clear_rpool(sc, group, large); return; } bzero(q->mem.base, q->mem.size); q->rbp = q->mem.base; q->head = q->tail = 0; DBG(sc, ATTACH, ("RBP%u%c=0x%lx", group, "SL"[large], (u_long)q->mem.paddr)); WRITE4(sc, HE_REGO_RBP_S(large, group), q->mem.paddr); WRITE4(sc, HE_REGO_RBP_T(large, group), 0); WRITE4(sc, HE_REGO_RBP_QI(large, group), ((q->size - 1) << HE_REGS_RBP_SIZE) | HE_REGM_RBP_INTR_ENB | (q->thresh << HE_REGS_RBP_THRESH)); WRITE4(sc, HE_REGO_RBP_BL(large, group), (q->bsize >> 2) & ~1); } /* * Clear an unused receive buffer return queue */ static void hatm_clear_rbrq(struct hatm_softc *sc, u_int group) { WRITE4(sc, HE_REGO_RBRQ_ST(group), 0); WRITE4(sc, HE_REGO_RBRQ_H(group), 0); WRITE4(sc, HE_REGO_RBRQ_Q(group), (1 << HE_REGS_RBRQ_THRESH)); WRITE4(sc, HE_REGO_RBRQ_I(group), 0); } /* * Initialize receive buffer return queue */ static void hatm_init_rbrq(struct hatm_softc *sc, struct herbrq *rq, u_int group) { if (rq->size == 0) { hatm_clear_rbrq(sc, group); return; } rq->rbrq = rq->mem.base; rq->head = 0; DBG(sc, ATTACH, ("RBRQ%u=0x%lx", group, (u_long)rq->mem.paddr)); WRITE4(sc, HE_REGO_RBRQ_ST(group), rq->mem.paddr); WRITE4(sc, HE_REGO_RBRQ_H(group), 0); WRITE4(sc, HE_REGO_RBRQ_Q(group), (rq->thresh << HE_REGS_RBRQ_THRESH) | ((rq->size - 1) << HE_REGS_RBRQ_SIZE)); WRITE4(sc, HE_REGO_RBRQ_I(group), (rq->tout << HE_REGS_RBRQ_TIME) | (rq->pcnt << HE_REGS_RBRQ_COUNT)); } /* * Clear an unused transmit buffer return queue N */ static void hatm_clear_tbrq(struct hatm_softc *sc, u_int group) { WRITE4(sc, HE_REGO_TBRQ_B_T(group), 0); WRITE4(sc, HE_REGO_TBRQ_H(group), 0); WRITE4(sc, HE_REGO_TBRQ_S(group), 0); WRITE4(sc, HE_REGO_TBRQ_THRESH(group), 1); } /* * Initialize transmit buffer return queue N */ static void hatm_init_tbrq(struct hatm_softc *sc, struct hetbrq *tq, u_int group) { if (tq->size == 0) { hatm_clear_tbrq(sc, group); return; } tq->tbrq = tq->mem.base; tq->head = 0; DBG(sc, ATTACH, ("TBRQ%u=0x%lx", group, (u_long)tq->mem.paddr)); WRITE4(sc, HE_REGO_TBRQ_B_T(group), tq->mem.paddr); WRITE4(sc, HE_REGO_TBRQ_H(group), 0); WRITE4(sc, HE_REGO_TBRQ_S(group), tq->size - 1); WRITE4(sc, HE_REGO_TBRQ_THRESH(group), tq->thresh); } /* * Initialize TPDRQ */ static void hatm_init_tpdrq(struct hatm_softc *sc) { struct hetpdrq *tq; tq = &sc->tpdrq; tq->tpdrq = tq->mem.base; tq->tail = tq->head = 0; DBG(sc, ATTACH, ("TPDRQ=0x%lx", (u_long)tq->mem.paddr)); WRITE4(sc, HE_REGO_TPDRQ_H, tq->mem.paddr); WRITE4(sc, HE_REGO_TPDRQ_T, 0); WRITE4(sc, HE_REGO_TPDRQ_S, tq->size - 1); } /* * Function can be called by the infrastructure to start the card. */ static void hatm_init(void *p) { struct hatm_softc *sc = p; mtx_lock(&sc->mtx); hatm_stop(sc); hatm_initialize(sc); mtx_unlock(&sc->mtx); } enum { CTL_ISTATS, }; /* * Sysctl handler */ static int hatm_sysctl(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; uint32_t *ret; int error; size_t len; switch (arg2) { case CTL_ISTATS: len = sizeof(sc->istats); break; default: panic("bad control code"); } ret = malloc(len, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); switch (arg2) { case CTL_ISTATS: sc->istats.mcc += READ4(sc, HE_REGO_MCC); sc->istats.oec += READ4(sc, HE_REGO_OEC); sc->istats.dcc += READ4(sc, HE_REGO_DCC); sc->istats.cec += READ4(sc, HE_REGO_CEC); bcopy(&sc->istats, ret, sizeof(sc->istats)); break; } mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, ret, len); free(ret, M_TEMP); return (error); } static int kenv_getuint(struct hatm_softc *sc, const char *var, u_int *ptr, u_int def, int rw) { char full[IFNAMSIZ + 3 + 20]; char *val, *end; u_int u; *ptr = def; if (rw != 0) { if (SYSCTL_ADD_UINT(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, var, CTLFLAG_RW, ptr, 0, "") == NULL) return (ENOMEM); } else { if (SYSCTL_ADD_UINT(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, var, CTLFLAG_RD, ptr, 0, "") == NULL) return (ENOMEM); } snprintf(full, sizeof(full), "hw.%s.%s", device_get_nameunit(sc->dev), var); if ((val = getenv(full)) == NULL) return (0); u = strtoul(val, &end, 0); if (end == val || *end != '\0') { freeenv(val); return (EINVAL); } freeenv(val); if (bootverbose) if_printf(sc->ifp, "%s=%u\n", full, u); *ptr = u; return (0); } /* * Set configurable parameters. Many of these are configurable via * kenv. */ static int hatm_configure(struct hatm_softc *sc) { /* Receive buffer pool 0 small */ kenv_getuint(sc, "rbps0_size", &sc->rbp_s0.size, HE_CONFIG_RBPS0_SIZE, 0); kenv_getuint(sc, "rbps0_thresh", &sc->rbp_s0.thresh, HE_CONFIG_RBPS0_THRESH, 0); sc->rbp_s0.bsize = MBUF0_SIZE; /* Receive buffer pool 0 large */ kenv_getuint(sc, "rbpl0_size", &sc->rbp_l0.size, HE_CONFIG_RBPL0_SIZE, 0); kenv_getuint(sc, "rbpl0_thresh", &sc->rbp_l0.thresh, HE_CONFIG_RBPL0_THRESH, 0); sc->rbp_l0.bsize = MCLBYTES - MBUFL_OFFSET; /* Receive buffer return queue 0 */ kenv_getuint(sc, "rbrq0_size", &sc->rbrq_0.size, HE_CONFIG_RBRQ0_SIZE, 0); kenv_getuint(sc, "rbrq0_thresh", &sc->rbrq_0.thresh, HE_CONFIG_RBRQ0_THRESH, 0); kenv_getuint(sc, "rbrq0_tout", &sc->rbrq_0.tout, HE_CONFIG_RBRQ0_TOUT, 0); kenv_getuint(sc, "rbrq0_pcnt", &sc->rbrq_0.pcnt, HE_CONFIG_RBRQ0_PCNT, 0); /* Receive buffer pool 1 small */ kenv_getuint(sc, "rbps1_size", &sc->rbp_s1.size, HE_CONFIG_RBPS1_SIZE, 0); kenv_getuint(sc, "rbps1_thresh", &sc->rbp_s1.thresh, HE_CONFIG_RBPS1_THRESH, 0); sc->rbp_s1.bsize = MBUF1_SIZE; /* Receive buffer return queue 1 */ kenv_getuint(sc, "rbrq1_size", &sc->rbrq_1.size, HE_CONFIG_RBRQ1_SIZE, 0); kenv_getuint(sc, "rbrq1_thresh", &sc->rbrq_1.thresh, HE_CONFIG_RBRQ1_THRESH, 0); kenv_getuint(sc, "rbrq1_tout", &sc->rbrq_1.tout, HE_CONFIG_RBRQ1_TOUT, 0); kenv_getuint(sc, "rbrq1_pcnt", &sc->rbrq_1.pcnt, HE_CONFIG_RBRQ1_PCNT, 0); /* Interrupt queue 0 */ kenv_getuint(sc, "irq0_size", &sc->irq_0.size, HE_CONFIG_IRQ0_SIZE, 0); kenv_getuint(sc, "irq0_thresh", &sc->irq_0.thresh, HE_CONFIG_IRQ0_THRESH, 0); sc->irq_0.line = HE_CONFIG_IRQ0_LINE; /* Transmit buffer return queue 0 */ kenv_getuint(sc, "tbrq0_size", &sc->tbrq.size, HE_CONFIG_TBRQ_SIZE, 0); kenv_getuint(sc, "tbrq0_thresh", &sc->tbrq.thresh, HE_CONFIG_TBRQ_THRESH, 0); /* Transmit buffer ready queue */ kenv_getuint(sc, "tpdrq_size", &sc->tpdrq.size, HE_CONFIG_TPDRQ_SIZE, 0); /* Max TPDs per VCC */ kenv_getuint(sc, "tpdmax", &sc->max_tpd, HE_CONFIG_TPD_MAXCC, 0); /* external mbuf pages */ kenv_getuint(sc, "max_mbuf_pages", &sc->mbuf_max_pages, HE_CONFIG_MAX_MBUF_PAGES, 0); /* mpsafe */ kenv_getuint(sc, "mpsafe", &sc->mpsafe, 0, 0); if (sc->mpsafe != 0) sc->mpsafe = INTR_MPSAFE; return (0); } #ifdef HATM_DEBUG /* * Get TSRs from connection memory */ static int hatm_sysctl_tsr(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i, j; uint32_t *val; val = malloc(sizeof(uint32_t) * HE_MAX_VCCS * 15, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); for (i = 0; i < HE_MAX_VCCS; i++) for (j = 0; j <= 14; j++) val[15 * i + j] = READ_TSR(sc, i, j); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, sizeof(uint32_t) * HE_MAX_VCCS * 15); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } /* * Get TPDs from connection memory */ static int hatm_sysctl_tpd(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i, j; uint32_t *val; val = malloc(sizeof(uint32_t) * HE_MAX_VCCS * 16, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); for (i = 0; i < HE_MAX_VCCS; i++) for (j = 0; j < 16; j++) val[16 * i + j] = READ_TCM4(sc, 16 * i + j); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, sizeof(uint32_t) * HE_MAX_VCCS * 16); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } /* * Get mbox registers */ static int hatm_sysctl_mbox(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i; uint32_t *val; val = malloc(sizeof(uint32_t) * HE_REGO_CS_END, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); for (i = 0; i < HE_REGO_CS_END; i++) val[i] = READ_MBOX4(sc, i); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, sizeof(uint32_t) * HE_REGO_CS_END); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } /* * Get connection memory */ static int hatm_sysctl_cm(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i; uint32_t *val; val = malloc(sizeof(uint32_t) * (HE_CONFIG_RXMEM + 1), M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); val[0] = READ4(sc, HE_REGO_RCMABR_BA); for (i = 0; i < HE_CONFIG_RXMEM; i++) val[i + 1] = READ_RCM4(sc, i); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, sizeof(uint32_t) * (HE_CONFIG_RXMEM + 1)); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } /* * Get local buffer memory */ static int hatm_sysctl_lbmem(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i; uint32_t *val; u_int bytes = (1 << 21); val = malloc(bytes, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); for (i = 0; i < bytes / 4; i++) val[i] = READ_LB4(sc, i); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, bytes); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } /* * Get all card registers */ static int hatm_sysctl_heregs(SYSCTL_HANDLER_ARGS) { struct hatm_softc *sc = arg1; int error, i; uint32_t *val; val = malloc(HE_REGO_END, M_TEMP, M_WAITOK); mtx_lock(&sc->mtx); for (i = 0; i < HE_REGO_END; i += 4) val[i / 4] = READ4(sc, i); mtx_unlock(&sc->mtx); error = SYSCTL_OUT(req, val, HE_REGO_END); free(val, M_TEMP); if (error != 0 || req->newptr == NULL) return (error); return (EPERM); } #endif /* * Suni register access */ /* * read at most n SUNI registers starting at reg into val */ static int hatm_utopia_readregs(struct ifatm *ifatm, u_int reg, uint8_t *val, u_int *n) { u_int i; struct hatm_softc *sc = ifatm->ifp->if_softc; if (reg >= (HE_REGO_SUNI_END - HE_REGO_SUNI) / 4) return (EINVAL); if (reg + *n > (HE_REGO_SUNI_END - HE_REGO_SUNI) / 4) *n = reg - (HE_REGO_SUNI_END - HE_REGO_SUNI) / 4; mtx_assert(&sc->mtx, MA_OWNED); for (i = 0; i < *n; i++) val[i] = READ4(sc, HE_REGO_SUNI + 4 * (reg + i)); return (0); } /* * change the bits given by mask to them in val in register reg */ static int hatm_utopia_writereg(struct ifatm *ifatm, u_int reg, u_int mask, u_int val) { uint32_t regval; struct hatm_softc *sc = ifatm->ifp->if_softc; if (reg >= (HE_REGO_SUNI_END - HE_REGO_SUNI) / 4) return (EINVAL); mtx_assert(&sc->mtx, MA_OWNED); regval = READ4(sc, HE_REGO_SUNI + 4 * reg); regval = (regval & ~mask) | (val & mask); WRITE4(sc, HE_REGO_SUNI + 4 * reg, regval); return (0); } static struct utopia_methods hatm_utopia_methods = { hatm_utopia_readregs, hatm_utopia_writereg, }; /* * Detach - if it is running, stop. Destroy. */ static int hatm_detach(device_t dev) { struct hatm_softc *sc = device_get_softc(dev); mtx_lock(&sc->mtx); hatm_stop(sc); if (sc->utopia.state & UTP_ST_ATTACHED) { utopia_stop(&sc->utopia); utopia_detach(&sc->utopia); } mtx_unlock(&sc->mtx); atm_ifdetach(sc->ifp); hatm_destroy(sc); return (0); } /* * Attach to the device. Assume that no locking is needed here. * All resource we allocate here are freed by calling hatm_destroy. */ static int hatm_attach(device_t dev) { struct hatm_softc *sc; int error; uint32_t v; struct ifnet *ifp; sc = device_get_softc(dev); ifp = sc->ifp = if_alloc(IFT_ATM); if (ifp == NULL) { device_printf(dev, "could not if_alloc()\n"); return (ENOSPC); } sc->dev = dev; IFP2IFATM(sc->ifp)->mib.device = ATM_DEVICE_HE155; IFP2IFATM(sc->ifp)->mib.serial = 0; IFP2IFATM(sc->ifp)->mib.hw_version = 0; IFP2IFATM(sc->ifp)->mib.sw_version = 0; IFP2IFATM(sc->ifp)->mib.vpi_bits = HE_CONFIG_VPI_BITS; IFP2IFATM(sc->ifp)->mib.vci_bits = HE_CONFIG_VCI_BITS; IFP2IFATM(sc->ifp)->mib.max_vpcs = 0; IFP2IFATM(sc->ifp)->mib.max_vccs = HE_MAX_VCCS; IFP2IFATM(sc->ifp)->mib.media = IFM_ATM_UNKNOWN; sc->he622 = 0; IFP2IFATM(sc->ifp)->phy = &sc->utopia; SLIST_INIT(&sc->tpd_free); mtx_init(&sc->mtx, device_get_nameunit(dev), MTX_NETWORK_LOCK, MTX_DEF); cv_init(&sc->vcc_cv, "HEVCCcv"); cv_init(&sc->cv_rcclose, "RCClose"); sysctl_ctx_init(&sc->sysctl_ctx); /* * 4.2 BIOS Configuration */ v = pci_read_config(dev, PCIR_COMMAND, 2); v |= PCIM_CMD_BUSMASTEREN | PCIM_CMD_MWRICEN; pci_write_config(dev, PCIR_COMMAND, v, 2); /* * 4.3 PCI Bus Controller-Specific Initialisation */ v = pci_read_config(dev, HE_PCIR_GEN_CNTL_0, 4); v |= HE_PCIM_CTL0_MRL | HE_PCIM_CTL0_MRM | HE_PCIM_CTL0_IGNORE_TIMEOUT; #if BYTE_ORDER == BIG_ENDIAN && 0 v |= HE_PCIM_CTL0_BIGENDIAN; #endif pci_write_config(dev, HE_PCIR_GEN_CNTL_0, v, 4); /* * Map memory */ sc->memid = PCIR_BAR(0); sc->memres = bus_alloc_resource_any(dev, SYS_RES_MEMORY, &sc->memid, RF_ACTIVE); if (sc->memres == NULL) { device_printf(dev, "could not map memory\n"); error = ENXIO; goto failed; } sc->memh = rman_get_bushandle(sc->memres); sc->memt = rman_get_bustag(sc->memres); /* * ALlocate a DMA tag for subsequent allocations */ if (bus_dma_tag_create(bus_get_dma_tag(sc->dev), 1, 0, BUS_SPACE_MAXADDR_32BIT, BUS_SPACE_MAXADDR, NULL, NULL, BUS_SPACE_MAXSIZE_32BIT, 1, BUS_SPACE_MAXSIZE_32BIT, 0, NULL, NULL, &sc->parent_tag)) { device_printf(dev, "could not allocate DMA tag\n"); error = ENOMEM; goto failed; } if (bus_dma_tag_create(sc->parent_tag, 1, 0, BUS_SPACE_MAXADDR_32BIT, BUS_SPACE_MAXADDR, NULL, NULL, MBUF_ALLOC_SIZE, 1, MBUF_ALLOC_SIZE, 0, NULL, NULL, &sc->mbuf_tag)) { device_printf(dev, "could not allocate mbuf DMA tag\n"); error = ENOMEM; goto failed; } /* * Allocate a DMA tag for packets to send. Here we have a problem with * the specification of the maximum number of segments. Theoretically * this would be the size of the transmit ring - 1 multiplied by 3, * but this would not work. So make the maximum number of TPDs * occupied by one packet a configuration parameter. */ if (bus_dma_tag_create(bus_get_dma_tag(sc->dev), 1, 0, BUS_SPACE_MAXADDR_32BIT, BUS_SPACE_MAXADDR, NULL, NULL, HE_MAX_PDU, 3 * HE_CONFIG_MAX_TPD_PER_PACKET, HE_MAX_PDU, 0, NULL, NULL, &sc->tx_tag)) { device_printf(dev, "could not allocate TX tag\n"); error = ENOMEM; goto failed; } /* * Setup the interrupt */ sc->irqid = 0; sc->irqres = bus_alloc_resource_any(dev, SYS_RES_IRQ, &sc->irqid, RF_SHAREABLE | RF_ACTIVE); if (sc->irqres == 0) { device_printf(dev, "could not allocate irq\n"); error = ENXIO; goto failed; } ifp->if_softc = sc; if_initname(ifp, device_get_name(dev), device_get_unit(dev)); /* * Make the sysctl tree */ error = ENOMEM; if ((sc->sysctl_tree = SYSCTL_ADD_NODE(&sc->sysctl_ctx, SYSCTL_STATIC_CHILDREN(_hw_atm), OID_AUTO, device_get_nameunit(dev), CTLFLAG_RD, 0, "")) == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "istats", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, CTL_ISTATS, hatm_sysctl, "LU", "internal statistics") == NULL) goto failed; #ifdef HATM_DEBUG if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "tsr", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_tsr, "S", "transmission status registers") == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "tpd", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_tpd, "S", "transmission packet descriptors") == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "mbox", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_mbox, "S", "mbox registers") == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "cm", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_cm, "S", "connection memory") == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "heregs", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_heregs, "S", "card registers") == NULL) goto failed; if (SYSCTL_ADD_PROC(&sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "lbmem", CTLFLAG_RD | CTLTYPE_OPAQUE, sc, 0, hatm_sysctl_lbmem, "S", "local memory") == NULL) goto failed; kenv_getuint(sc, "debug", &sc->debug, HATM_DEBUG, 1); #endif /* * Configure */ if ((error = hatm_configure(sc)) != 0) goto failed; /* * Compute memory parameters */ if (sc->rbp_s0.size != 0) { sc->rbp_s0.mask = (sc->rbp_s0.size - 1) << 3; sc->rbp_s0.mem.size = sc->rbp_s0.size * 8; sc->rbp_s0.mem.align = sc->rbp_s0.mem.size; } if (sc->rbp_l0.size != 0) { sc->rbp_l0.mask = (sc->rbp_l0.size - 1) << 3; sc->rbp_l0.mem.size = sc->rbp_l0.size * 8; sc->rbp_l0.mem.align = sc->rbp_l0.mem.size; } if (sc->rbp_s1.size != 0) { sc->rbp_s1.mask = (sc->rbp_s1.size - 1) << 3; sc->rbp_s1.mem.size = sc->rbp_s1.size * 8; sc->rbp_s1.mem.align = sc->rbp_s1.mem.size; } if (sc->rbrq_0.size != 0) { sc->rbrq_0.mem.size = sc->rbrq_0.size * 8; sc->rbrq_0.mem.align = sc->rbrq_0.mem.size; } if (sc->rbrq_1.size != 0) { sc->rbrq_1.mem.size = sc->rbrq_1.size * 8; sc->rbrq_1.mem.align = sc->rbrq_1.mem.size; } sc->irq_0.mem.size = sc->irq_0.size * sizeof(uint32_t); sc->irq_0.mem.align = 4 * 1024; sc->tbrq.mem.size = sc->tbrq.size * 4; sc->tbrq.mem.align = 2 * sc->tbrq.mem.size; /* ZZZ */ sc->tpdrq.mem.size = sc->tpdrq.size * 8; sc->tpdrq.mem.align = sc->tpdrq.mem.size; sc->hsp_mem.size = sizeof(struct he_hsp); sc->hsp_mem.align = 1024; sc->lbufs_size = sc->rbp_l0.size + sc->rbrq_0.size; sc->tpd_total = sc->tbrq.size + sc->tpdrq.size; sc->tpds.align = 64; sc->tpds.size = sc->tpd_total * HE_TPD_SIZE; hatm_init_rmaps(sc); hatm_init_smbufs(sc); if ((error = hatm_init_tpds(sc)) != 0) goto failed; /* * Allocate memory */ if ((error = hatm_alloc_dmamem(sc, "IRQ", &sc->irq_0.mem)) != 0 || (error = hatm_alloc_dmamem(sc, "TBRQ0", &sc->tbrq.mem)) != 0 || (error = hatm_alloc_dmamem(sc, "TPDRQ", &sc->tpdrq.mem)) != 0 || (error = hatm_alloc_dmamem(sc, "HSP", &sc->hsp_mem)) != 0) goto failed; if (sc->rbp_s0.mem.size != 0 && (error = hatm_alloc_dmamem(sc, "RBPS0", &sc->rbp_s0.mem))) goto failed; if (sc->rbp_l0.mem.size != 0 && (error = hatm_alloc_dmamem(sc, "RBPL0", &sc->rbp_l0.mem))) goto failed; if (sc->rbp_s1.mem.size != 0 && (error = hatm_alloc_dmamem(sc, "RBPS1", &sc->rbp_s1.mem))) goto failed; if (sc->rbrq_0.mem.size != 0 && (error = hatm_alloc_dmamem(sc, "RBRQ0", &sc->rbrq_0.mem))) goto failed; if (sc->rbrq_1.mem.size != 0 && (error = hatm_alloc_dmamem(sc, "RBRQ1", &sc->rbrq_1.mem))) goto failed; if ((sc->vcc_zone = uma_zcreate("HE vccs", sizeof(struct hevcc), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0)) == NULL) { device_printf(dev, "cannot allocate zone for vccs\n"); goto failed; } /* * 4.4 Reset the card. */ if ((error = hatm_reset(sc)) != 0) goto failed; /* * Read the prom. */ hatm_init_bus_width(sc); hatm_init_read_eeprom(sc); hatm_init_endianess(sc); /* * Initialize interface */ ifp->if_flags = IFF_SIMPLEX; ifp->if_ioctl = hatm_ioctl; ifp->if_start = hatm_start; ifp->if_init = hatm_init; utopia_attach(&sc->utopia, IFP2IFATM(sc->ifp), &sc->media, &sc->mtx, &sc->sysctl_ctx, SYSCTL_CHILDREN(sc->sysctl_tree), &hatm_utopia_methods); utopia_init_media(&sc->utopia); /* these two SUNI routines need the lock */ mtx_lock(&sc->mtx); /* poll while we are not running */ sc->utopia.flags |= UTP_FL_POLL_CARRIER; utopia_start(&sc->utopia); utopia_reset(&sc->utopia); mtx_unlock(&sc->mtx); atm_ifattach(ifp); #ifdef ENABLE_BPF bpfattach(ifp, DLT_ATM_RFC1483, sizeof(struct atmllc)); #endif error = bus_setup_intr(dev, sc->irqres, sc->mpsafe | INTR_TYPE_NET, NULL, hatm_intr, &sc->irq_0, &sc->ih); if (error != 0) { device_printf(dev, "could not setup interrupt\n"); hatm_detach(dev); return (error); } return (0); failed: hatm_destroy(sc); return (error); } /* * Start the interface. Assume a state as from attach(). */ void hatm_initialize(struct hatm_softc *sc) { uint32_t v; u_int cid; static const u_int layout[2][7] = HE_CONFIG_MEM_LAYOUT; if (sc->ifp->if_drv_flags & IFF_DRV_RUNNING) return; hatm_init_bus_width(sc); hatm_init_endianess(sc); if_printf(sc->ifp, "%s, Rev. %s, S/N %u, " "MAC=%02x:%02x:%02x:%02x:%02x:%02x (%ubit PCI)\n", sc->prod_id, sc->rev, IFP2IFATM(sc->ifp)->mib.serial, IFP2IFATM(sc->ifp)->mib.esi[0], IFP2IFATM(sc->ifp)->mib.esi[1], IFP2IFATM(sc->ifp)->mib.esi[2], IFP2IFATM(sc->ifp)->mib.esi[3], IFP2IFATM(sc->ifp)->mib.esi[4], IFP2IFATM(sc->ifp)->mib.esi[5], sc->pci64 ? 64 : 32); /* * 4.8 SDRAM Controller Initialisation * 4.9 Initialize RNUM value */ if (sc->he622) WRITE4(sc, HE_REGO_SDRAM_CNTL, HE_REGM_SDRAM_64BIT); else WRITE4(sc, HE_REGO_SDRAM_CNTL, 0); BARRIER_W(sc); v = READ4(sc, HE_REGO_LB_SWAP); BARRIER_R(sc); v |= 0xf << HE_REGS_LBSWAP_RNUM; WRITE4(sc, HE_REGO_LB_SWAP, v); BARRIER_W(sc); hatm_init_irq(sc, &sc->irq_0, 0); hatm_clear_irq(sc, 1); hatm_clear_irq(sc, 2); hatm_clear_irq(sc, 3); WRITE4(sc, HE_REGO_GRP_1_0_MAP, 0); WRITE4(sc, HE_REGO_GRP_3_2_MAP, 0); WRITE4(sc, HE_REGO_GRP_5_4_MAP, 0); WRITE4(sc, HE_REGO_GRP_7_6_MAP, 0); BARRIER_W(sc); /* * 4.11 Enable PCI Bus Controller State Machine */ v = READ4(sc, HE_REGO_HOST_CNTL); BARRIER_R(sc); v |= HE_REGM_HOST_OUTFF_ENB | HE_REGM_HOST_CMDFF_ENB | HE_REGM_HOST_QUICK_RD | HE_REGM_HOST_QUICK_WR; WRITE4(sc, HE_REGO_HOST_CNTL, v); BARRIER_W(sc); /* * 5.1.1 Generic configuration state */ sc->cells_per_row = layout[sc->he622][0]; sc->bytes_per_row = layout[sc->he622][1]; sc->r0_numrows = layout[sc->he622][2]; sc->tx_numrows = layout[sc->he622][3]; sc->r1_numrows = layout[sc->he622][4]; sc->r0_startrow = layout[sc->he622][5]; sc->tx_startrow = sc->r0_startrow + sc->r0_numrows; sc->r1_startrow = sc->tx_startrow + sc->tx_numrows; sc->cells_per_lbuf = layout[sc->he622][6]; sc->r0_numbuffs = sc->r0_numrows * (sc->cells_per_row / sc->cells_per_lbuf); sc->r1_numbuffs = sc->r1_numrows * (sc->cells_per_row / sc->cells_per_lbuf); sc->tx_numbuffs = sc->tx_numrows * (sc->cells_per_row / sc->cells_per_lbuf); if (sc->r0_numbuffs > 2560) sc->r0_numbuffs = 2560; if (sc->r1_numbuffs > 2560) sc->r1_numbuffs = 2560; if (sc->tx_numbuffs > 5120) sc->tx_numbuffs = 5120; DBG(sc, ATTACH, ("cells_per_row=%u bytes_per_row=%u r0_numrows=%u " "tx_numrows=%u r1_numrows=%u r0_startrow=%u tx_startrow=%u " "r1_startrow=%u cells_per_lbuf=%u\nr0_numbuffs=%u r1_numbuffs=%u " "tx_numbuffs=%u\n", sc->cells_per_row, sc->bytes_per_row, sc->r0_numrows, sc->tx_numrows, sc->r1_numrows, sc->r0_startrow, sc->tx_startrow, sc->r1_startrow, sc->cells_per_lbuf, sc->r0_numbuffs, sc->r1_numbuffs, sc->tx_numbuffs)); /* * 5.1.2 Configure Hardware dependend registers */ if (sc->he622) { WRITE4(sc, HE_REGO_LBARB, (0x2 << HE_REGS_LBARB_SLICE) | (0xf << HE_REGS_LBARB_RNUM) | (0x3 << HE_REGS_LBARB_THPRI) | (0x3 << HE_REGS_LBARB_RHPRI) | (0x2 << HE_REGS_LBARB_TLPRI) | (0x1 << HE_REGS_LBARB_RLPRI) | (0x28 << HE_REGS_LBARB_BUS_MULT) | (0x50 << HE_REGS_LBARB_NET_PREF)); BARRIER_W(sc); WRITE4(sc, HE_REGO_SDRAMCON, /* HW bug: don't use banking */ /* HE_REGM_SDRAMCON_BANK | */ HE_REGM_SDRAMCON_WIDE | (0x384 << HE_REGS_SDRAMCON_REF)); BARRIER_W(sc); WRITE4(sc, HE_REGO_RCMCONFIG, (0x1 << HE_REGS_RCMCONFIG_BANK_WAIT) | (0x1 << HE_REGS_RCMCONFIG_RW_WAIT) | (0x0 << HE_REGS_RCMCONFIG_TYPE)); WRITE4(sc, HE_REGO_TCMCONFIG, (0x2 << HE_REGS_TCMCONFIG_BANK_WAIT) | (0x1 << HE_REGS_TCMCONFIG_RW_WAIT) | (0x0 << HE_REGS_TCMCONFIG_TYPE)); } else { WRITE4(sc, HE_REGO_LBARB, (0x2 << HE_REGS_LBARB_SLICE) | (0xf << HE_REGS_LBARB_RNUM) | (0x3 << HE_REGS_LBARB_THPRI) | (0x3 << HE_REGS_LBARB_RHPRI) | (0x2 << HE_REGS_LBARB_TLPRI) | (0x1 << HE_REGS_LBARB_RLPRI) | (0x46 << HE_REGS_LBARB_BUS_MULT) | (0x8C << HE_REGS_LBARB_NET_PREF)); BARRIER_W(sc); WRITE4(sc, HE_REGO_SDRAMCON, /* HW bug: don't use banking */ /* HE_REGM_SDRAMCON_BANK | */ (0x150 << HE_REGS_SDRAMCON_REF)); BARRIER_W(sc); WRITE4(sc, HE_REGO_RCMCONFIG, (0x0 << HE_REGS_RCMCONFIG_BANK_WAIT) | (0x1 << HE_REGS_RCMCONFIG_RW_WAIT) | (0x0 << HE_REGS_RCMCONFIG_TYPE)); WRITE4(sc, HE_REGO_TCMCONFIG, (0x1 << HE_REGS_TCMCONFIG_BANK_WAIT) | (0x1 << HE_REGS_TCMCONFIG_RW_WAIT) | (0x0 << HE_REGS_TCMCONFIG_TYPE)); } WRITE4(sc, HE_REGO_LBCONFIG, (sc->cells_per_lbuf * 48)); WRITE4(sc, HE_REGO_RLBC_H, 0); WRITE4(sc, HE_REGO_RLBC_T, 0); WRITE4(sc, HE_REGO_RLBC_H2, 0); WRITE4(sc, HE_REGO_RXTHRSH, 512); WRITE4(sc, HE_REGO_LITHRSH, 256); WRITE4(sc, HE_REGO_RLBF0_C, sc->r0_numbuffs); WRITE4(sc, HE_REGO_RLBF1_C, sc->r1_numbuffs); if (sc->he622) { WRITE4(sc, HE_REGO_RCCONFIG, (8 << HE_REGS_RCCONFIG_UTDELAY) | (IFP2IFATM(sc->ifp)->mib.vpi_bits << HE_REGS_RCCONFIG_VP) | (IFP2IFATM(sc->ifp)->mib.vci_bits << HE_REGS_RCCONFIG_VC)); WRITE4(sc, HE_REGO_TXCONFIG, (32 << HE_REGS_TXCONFIG_THRESH) | (IFP2IFATM(sc->ifp)->mib.vci_bits << HE_REGS_TXCONFIG_VCI_MASK) | (sc->tx_numbuffs << HE_REGS_TXCONFIG_LBFREE)); } else { WRITE4(sc, HE_REGO_RCCONFIG, (0 << HE_REGS_RCCONFIG_UTDELAY) | HE_REGM_RCCONFIG_UT_MODE | (IFP2IFATM(sc->ifp)->mib.vpi_bits << HE_REGS_RCCONFIG_VP) | (IFP2IFATM(sc->ifp)->mib.vci_bits << HE_REGS_RCCONFIG_VC)); WRITE4(sc, HE_REGO_TXCONFIG, (32 << HE_REGS_TXCONFIG_THRESH) | HE_REGM_TXCONFIG_UTMODE | (IFP2IFATM(sc->ifp)->mib.vci_bits << HE_REGS_TXCONFIG_VCI_MASK) | (sc->tx_numbuffs << HE_REGS_TXCONFIG_LBFREE)); } WRITE4(sc, HE_REGO_TXAAL5_PROTO, 0); if (sc->rbp_s1.size != 0) { WRITE4(sc, HE_REGO_RHCONFIG, HE_REGM_RHCONFIG_PHYENB | ((sc->he622 ? 0x41 : 0x31) << HE_REGS_RHCONFIG_PTMR_PRE) | (1 << HE_REGS_RHCONFIG_OAM_GID)); } else { WRITE4(sc, HE_REGO_RHCONFIG, HE_REGM_RHCONFIG_PHYENB | ((sc->he622 ? 0x41 : 0x31) << HE_REGS_RHCONFIG_PTMR_PRE) | (0 << HE_REGS_RHCONFIG_OAM_GID)); } BARRIER_W(sc); hatm_init_cm(sc); hatm_init_rx_buffer_pool(sc, 0, sc->r0_startrow, sc->r0_numbuffs); hatm_init_rx_buffer_pool(sc, 1, sc->r1_startrow, sc->r1_numbuffs); hatm_init_tx_buffer_pool(sc, sc->tx_startrow, sc->tx_numbuffs); hatm_init_imed_queues(sc); /* * 5.1.6 Application tunable Parameters */ WRITE4(sc, HE_REGO_MCC, 0); WRITE4(sc, HE_REGO_OEC, 0); WRITE4(sc, HE_REGO_DCC, 0); WRITE4(sc, HE_REGO_CEC, 0); hatm_init_cs_block(sc); hatm_init_cs_block_cm(sc); hatm_init_rpool(sc, &sc->rbp_s0, 0, 0); hatm_init_rpool(sc, &sc->rbp_l0, 0, 1); hatm_init_rpool(sc, &sc->rbp_s1, 1, 0); hatm_clear_rpool(sc, 1, 1); hatm_clear_rpool(sc, 2, 0); hatm_clear_rpool(sc, 2, 1); hatm_clear_rpool(sc, 3, 0); hatm_clear_rpool(sc, 3, 1); hatm_clear_rpool(sc, 4, 0); hatm_clear_rpool(sc, 4, 1); hatm_clear_rpool(sc, 5, 0); hatm_clear_rpool(sc, 5, 1); hatm_clear_rpool(sc, 6, 0); hatm_clear_rpool(sc, 6, 1); hatm_clear_rpool(sc, 7, 0); hatm_clear_rpool(sc, 7, 1); hatm_init_rbrq(sc, &sc->rbrq_0, 0); hatm_init_rbrq(sc, &sc->rbrq_1, 1); hatm_clear_rbrq(sc, 2); hatm_clear_rbrq(sc, 3); hatm_clear_rbrq(sc, 4); hatm_clear_rbrq(sc, 5); hatm_clear_rbrq(sc, 6); hatm_clear_rbrq(sc, 7); sc->lbufs_next = 0; bzero(sc->lbufs, sizeof(sc->lbufs[0]) * sc->lbufs_size); hatm_init_tbrq(sc, &sc->tbrq, 0); hatm_clear_tbrq(sc, 1); hatm_clear_tbrq(sc, 2); hatm_clear_tbrq(sc, 3); hatm_clear_tbrq(sc, 4); hatm_clear_tbrq(sc, 5); hatm_clear_tbrq(sc, 6); hatm_clear_tbrq(sc, 7); hatm_init_tpdrq(sc); WRITE4(sc, HE_REGO_UBUFF_BA, (sc->he622 ? 0x104780 : 0x800)); /* * Initialize HSP */ bzero(sc->hsp_mem.base, sc->hsp_mem.size); sc->hsp = sc->hsp_mem.base; WRITE4(sc, HE_REGO_HSP_BA, sc->hsp_mem.paddr); /* * 5.1.12 Enable transmit and receive * Enable bus master and interrupts */ v = READ_MBOX4(sc, HE_REGO_CS_ERCTL0); v |= 0x18000000; WRITE_MBOX4(sc, HE_REGO_CS_ERCTL0, v); v = READ4(sc, HE_REGO_RCCONFIG); v |= HE_REGM_RCCONFIG_RXENB; WRITE4(sc, HE_REGO_RCCONFIG, v); v = pci_read_config(sc->dev, HE_PCIR_GEN_CNTL_0, 4); v |= HE_PCIM_CTL0_INIT_ENB | HE_PCIM_CTL0_INT_PROC_ENB; pci_write_config(sc->dev, HE_PCIR_GEN_CNTL_0, v, 4); sc->ifp->if_drv_flags |= IFF_DRV_RUNNING; sc->ifp->if_baudrate = 53 * 8 * IFP2IFATM(sc->ifp)->mib.pcr; sc->utopia.flags &= ~UTP_FL_POLL_CARRIER; /* reopen vccs */ for (cid = 0; cid < HE_MAX_VCCS; cid++) if (sc->vccs[cid] != NULL) hatm_load_vc(sc, cid, 1); ATMEV_SEND_IFSTATE_CHANGED(IFP2IFATM(sc->ifp), sc->utopia.carrier == UTP_CARR_OK); } /* * This functions stops the card and frees all resources allocated after * the attach. Must have the global lock. */ void hatm_stop(struct hatm_softc *sc) { uint32_t v; u_int i, p, cid; struct mbuf_chunk_hdr *ch; struct mbuf_page *pg; mtx_assert(&sc->mtx, MA_OWNED); if (!(sc->ifp->if_drv_flags & IFF_DRV_RUNNING)) return; sc->ifp->if_drv_flags &= ~IFF_DRV_RUNNING; ATMEV_SEND_IFSTATE_CHANGED(IFP2IFATM(sc->ifp), sc->utopia.carrier == UTP_CARR_OK); sc->utopia.flags |= UTP_FL_POLL_CARRIER; /* * Stop and reset the hardware so that everything remains * stable. */ v = READ_MBOX4(sc, HE_REGO_CS_ERCTL0); v &= ~0x18000000; WRITE_MBOX4(sc, HE_REGO_CS_ERCTL0, v); v = READ4(sc, HE_REGO_RCCONFIG); v &= ~HE_REGM_RCCONFIG_RXENB; WRITE4(sc, HE_REGO_RCCONFIG, v); WRITE4(sc, HE_REGO_RHCONFIG, (0x2 << HE_REGS_RHCONFIG_PTMR_PRE)); BARRIER_W(sc); v = READ4(sc, HE_REGO_HOST_CNTL); BARRIER_R(sc); v &= ~(HE_REGM_HOST_OUTFF_ENB | HE_REGM_HOST_CMDFF_ENB); WRITE4(sc, HE_REGO_HOST_CNTL, v); BARRIER_W(sc); /* * Disable bust master and interrupts */ v = pci_read_config(sc->dev, HE_PCIR_GEN_CNTL_0, 4); v &= ~(HE_PCIM_CTL0_INIT_ENB | HE_PCIM_CTL0_INT_PROC_ENB); pci_write_config(sc->dev, HE_PCIR_GEN_CNTL_0, v, 4); (void)hatm_reset(sc); /* * Card resets the SUNI when resetted, so re-initialize it */ utopia_reset(&sc->utopia); /* * Give any waiters on closing a VCC a chance. They will stop * to wait if they see that IFF_DRV_RUNNING disappeared. */ cv_broadcast(&sc->vcc_cv); cv_broadcast(&sc->cv_rcclose); /* * Now free all resources. */ /* * Free the large mbufs that are given to the card. */ for (i = 0 ; i < sc->lbufs_size; i++) { if (sc->lbufs[i] != NULL) { bus_dmamap_unload(sc->mbuf_tag, sc->rmaps[i]); m_freem(sc->lbufs[i]); sc->lbufs[i] = NULL; } } /* * Free small buffers */ for (p = 0; p < sc->mbuf_npages; p++) { pg = sc->mbuf_pages[p]; for (i = 0; i < pg->hdr.nchunks; i++) { ch = (struct mbuf_chunk_hdr *) ((char *)pg + i * pg->hdr.chunksize + pg->hdr.hdroff); if (ch->flags & MBUF_CARD) { ch->flags &= ~MBUF_CARD; ch->flags |= MBUF_USED; hatm_ext_free(&sc->mbuf_list[pg->hdr.pool], (struct mbufx_free *)((u_char *)ch - pg->hdr.hdroff)); } } } hatm_stop_tpds(sc); /* * Free all partial reassembled PDUs on any VCC. */ for (cid = 0; cid < HE_MAX_VCCS; cid++) { if (sc->vccs[cid] != NULL) { if (sc->vccs[cid]->chain != NULL) { m_freem(sc->vccs[cid]->chain); sc->vccs[cid]->chain = NULL; sc->vccs[cid]->last = NULL; } if (!(sc->vccs[cid]->vflags & (HE_VCC_RX_OPEN | HE_VCC_TX_OPEN))) { hatm_tx_vcc_closed(sc, cid); uma_zfree(sc->vcc_zone, sc->vccs[cid]); sc->vccs[cid] = NULL; sc->open_vccs--; } else { sc->vccs[cid]->vflags = 0; sc->vccs[cid]->ntpds = 0; } } } if (sc->rbp_s0.size != 0) bzero(sc->rbp_s0.mem.base, sc->rbp_s0.mem.size); if (sc->rbp_l0.size != 0) bzero(sc->rbp_l0.mem.base, sc->rbp_l0.mem.size); if (sc->rbp_s1.size != 0) bzero(sc->rbp_s1.mem.base, sc->rbp_s1.mem.size); if (sc->rbrq_0.size != 0) bzero(sc->rbrq_0.mem.base, sc->rbrq_0.mem.size); if (sc->rbrq_1.size != 0) bzero(sc->rbrq_1.mem.base, sc->rbrq_1.mem.size); bzero(sc->tbrq.mem.base, sc->tbrq.mem.size); bzero(sc->tpdrq.mem.base, sc->tpdrq.mem.size); bzero(sc->hsp_mem.base, sc->hsp_mem.size); } /************************************************************ * * Driver infrastructure */ devclass_t hatm_devclass; static device_method_t hatm_methods[] = { DEVMETHOD(device_probe, hatm_probe), DEVMETHOD(device_attach, hatm_attach), DEVMETHOD(device_detach, hatm_detach), {0,0} }; static driver_t hatm_driver = { "hatm", hatm_methods, sizeof(struct hatm_softc), }; DRIVER_MODULE(hatm, pci, hatm_driver, hatm_devclass, NULL, 0);